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Mecanica cuantica: el gato de Schrodinger
Vea más en http://buenrato.blogspot.com/
El experimento del gato de Schrödinger o paradoja de Schrödinger es un experimento imaginario, diseñado por Erwin Schrödinger para exponer uno de los aspectos más extraños, a priori, de la mecánica cuántica.
La paradoja ha sido objeto de tanta controversia (y de discusión no sólo cientÃfica, sino hasta filosófica) que Schrödinger llegó a afirmar que "cada vez que escucho hablar de ese gato, empiezo a sacar mi pistola".
Length: 124
Rating: 4.60 (141 ratings)
Tags: buenrato documentales ciencia fisica mecanica cuantica experimento gato Schrodinger
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Schrödinger has something to say....
(EDIT) 20,000 bloody pageviews? Well, thanks for the support, but please... watch my other AMV's.... and look-up Tra5252 and check out her work. Do it now, I command you.
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'Cause Schro and the Captain are nothin' but mammals, so let 'em do it like they do on the discovery channel...
xD
Just a quick present I tossed together for Gren, Tra5252.
She likes Schro, so when the new OVA came out...well, I felt like making her a special present.
;)
Although I was a little irked whilst making this...there are no Captain clips in the OVA!!
D;
OKAY, TO CLARIFY...
1. I do enjoy yaoi sometimes, but this video was made for HUMOR.
2. I do not support the CaptainxSchro pairing, I just made it for a good friend of mine who does.
More facts:
3. SCHRO. IS. A. BOY.
4. Schro is NOT a werewolf....nor is Rip....or Zorin....
by the way, the fanart I used...credit goes to
littlemute
sutinen
and GrypsCelsus
all of whom are on DA, I give them full credit.
All those who are not Gren or do not have a catboy fetish, I deeply apologize. XD
The second song played in the credits is The Sunny Side of The Street, performed by Cyndi Lauper. So there it is, quite asking. XD
Length: 141
Rating: 4.70 (177 ratings)
Tags: Hellsing Ultimate OVA IV Schrodinger The Bad Touch crack AMV
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Real Quantum Mechanics: Video 2A -- The Schrodinger Equation
I MISSPELLED Mechanics in title...haha....I also misspelled "boundaries" and "schrodinger" in this vid...Just wanted to announce that so i don't get a horde of people correcting my english...Good thing spelling has nothing to do with physics..otherwise, i'd be terrible in the latter ANYWAYS......In this vid, I briefly go over the schrodinger eq and its time independent version....I also introduce the two requirements of a wavefuntion (to be valid in Quantum Mechanics)
Length: 354
Rating: 4.80 (22 ratings)
Tags: quantum mechanics physics schrodinger equation wavefunction state collapse reality wave function Premiere_Elements_4
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Warrant Officer Schrödinger on 6 minutes
This was Schrödinger, next time i will draw ALUCARD! :) This took 1 and a half hour to draw. You can find the picture in Hellsing Volume 4, page 83.
Oops... I forgot to write the letter c in Schrödinger O_o
Now it says Shrödinger X|
Take a closer look:
http://www.deviantart.com/deviation/60301405/
Length: 434
Rating: 4.50 (15 ratings)
Tags: Varrant Warrant Officer Schrödinger Schrodinger drawn by me
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Schrodinger Equation (seq 2 Common Sense Quantum Physics)
Schrodinger Equation made easy.
Here's the videoscript.
Hello, I'm Arjen, the Common Sense Quantum Physicist. My goal is to develop intuitive approaches to Quantum Physics. In a first sequence, about the polarization of light, we saw that quantum particles and particularly those composing light, the photons, are best represented by spinning linear objects, like arrows or needles or rods.
This time, we'll look at how we may characterize the physics of arrows. A famous physicist, Paul Dirac, in this reference book on the Principles of Quantum Mechanics, proposed to call them ket vectors, or simply kets [k e t], and denote a general one of them by a special symbol | "GT". If we want to specify a particular one of them be a label, A say, we insert it in the middle, thus vertical bar A greater than sign.
So, a ket is nothing more than a rotating arrow... Well, nearly nothing more. Physicists perform operating rules on it. These rules tell us how an arrow is transformed into another arrow, these rules also tell us that you may add the arrows in order to get another arrow, or multiply them or subtract them one from another. Let me present some of these operations.
Firstly, there is the operation where the arrow is rotated by an angle alpha. We multiply ket |A"GT" by a so called complex number to describe this rotation: exp(i alpha). So when you see a complex number in quantum-mechanical expressions, it is real physics. It simply means that ket |A"GT" has undergone a rotation in its spinning surface.
Secondly, you may add arrows by positionning them head to tail and then imagining the resultant arrow.
So this arrow |A"GT" plus this arrow |B"GT" equals this arrow |C"GT".
Subtracting is easy, you just imagine the arrow pointing towards the other side. So, subtracting ket |B"GT" from ket |A"GT" is the same as adding arrow -|B"GT" to arrow |A"GT" and this gives arrow |D"GT".
Multiplying by a real number is also easy.
2 * arrow |A"GT" just means |A"GT"+|A"GT" and 0.5 * arrow |A"GT" is just the operation that halves the arrow |A"GT".
So now that we know some basics of computing with arrows, let us describe an ordinary situation, for example the rotating motion of this arrow.
We already saw that |B"GT" = exp(i alpha) * |A"GT" just means that in order to obtain arrow |B"GT", arrow |A"GT" has been rotated by an angle alpha.
If we know the constant angular speed at which this arrow spins, we could replace the angle alpha by the expression (angular speed omega * interval of time). So we could also say:
Arrow |B"GT" equates exp(i * angular speed omega * difference (final time -- initial time)) * arrow |A"GT"
[written: |B"GT" = exp(i omega Delta(t)) |A"GT"]
This is the time evolution law for a freely spinning arrow.
However this is valid only for arrows that spin with a constant angular speed. So this equation has a very limited domain of validity. In real life a rotating linear object is generally subject to various forces. This arrow is subject to the forces of my hand, the motion of the blades of a windmill depends on the force of the wind and the motion of the spokes of this bicycle is bound to the motion impinged on the wheel.
So how could we describe the physics in the general case? Well, the trick is to look at very tiny intervals of time, which is called a differential of time and written dt. After a very tiny interval of time, the arrow |A"GT" is rotated over a very tiny angle omega * dt. The difference between the two very close positions of arrow |A"GT" is also a differential. Remember the head to tail rule. It is the little arrow d|A"GT" that is obtained by subtracting the initial |A"GT" from the subsequent |A"GT".
But there is another way to write the little arrow d|A"GT". Imagine the time interval going to the limit 0. Then the tiny arrow d|A"GT" makes an angle of 90° with |A"GT". This means that you may obtain the arrow d|A"GT" from |A"GT" not only by subtraction but also through a rotation of 90° and a reduction of the arrow by the proportionality factor (instantaneous angular speed omega * dt). That's just multiplying arrow |A"GT" by exp (i 90°) * instantaneous angular speed * dt. Well, you may have learned at high school that exp (i 90°) is the same as the imaginary i. So we may write in compact form:
d|A"GT"= i omega * dt |A"GT"
which is the generalized form of Schrodinger's time-dependent equation. Physicists generally multiply both terms of this equation by a fundamental constant hbar and reverse the time direction. This equation just describes common sense physics of ordinary arrow-like objects, for which the rotational speed at the tips of the arrow always make an angle of 90° with the arrow.
Now, when you ride your bike, remember the spokes obey the Schrodinger equation.
Next time we'll look at how arrow-like objects interact.
Length: 481
Rating: 5.00 (2 ratings)
Tags: Quantum Mechanics Physics Schrodinger Equation explained Hamiltonian Dirac Planck Ket Vector Arrow Arjen Dijksman
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